I'm reading some C code embedded with a few assembly code. I understand that __asm__ is a statement to run assembly code, but what does __asm__ do in the following code? According to the output (i.e., r = 16), it seems that __asm__ does not effect the variable r. Isn't it?

#include <stdio.h>
static void foo()
    static volatile unsigned int r __asm__ ("0x0019");
    r |= 1 << 4;

    printf("foo: %u\n", r);

Platform: Apple LLVM version 6.0 (clang-600.0.56) (based on LLVM 3.5svn) on OSX Yosemite

  • 2
    What compiler and platform? – interjay Dec 27 '14 at 20:24
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    It might mean that r is the value of the memory word of address 0x0019 – Basile Starynkevitch Dec 27 '14 at 20:29
  • 2
    The syntax looks a bit like gcc's global variable registers, although I can only guess about the meaning of 0x0019. – NPE Dec 27 '14 at 20:36
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    @Zilong: Out of interest, what's the context here? Is that user space code? Does it appear exactly as shown in your question? To the best of your understanding, what does it do? – NPE Dec 27 '14 at 20:40
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    One approach (if reading the manual doesn't help) is to compile with -S and examine the generated assembly code. Try with and without the __asm__ and compare to see just what effect the __asm__ has. Where did this code come from? Does the context (which you haven't shared with us) tell you what it's supposed to do, or even whether it does anything? – Keith Thompson Dec 27 '14 at 21:10

Strictly speaking, your "asm" snippet simply loads a constant (0x0019).

Here's a 32-bit example:

#include <stdio.h>
static void foo()
    static volatile unsigned int r __asm__ ("0x0019");
    static volatile unsigned int s __asm__ ("0x1122");
    static volatile unsigned int t = 0x3344;
    printf("foo: %u %u %u\n", r, s, t);

gcc -O0 -S x.c

cat x.c
        .file   "x.c"
        .align 4
        .type   t.1781, @object
        .size   t.1781, 4
        .long   13124  # Note: 13124 decimal == 0x3344 hex
        .local  0x1122
        .comm   0x1122,4,4
        .local  0x0019
        .comm   0x0019,4,4
        .section        .rodata
        .string "foo: %u %u %u\n"
        .type   foo, @function
        pushl   %ebp
        movl    %esp, %ebp
        subl    $24, %esp
        movl    t.1781, %eax
        movl    0x1122, %edx
        movl    0x0019, %ecx
        movl    %eax, 12(%esp)
        movl    %edx, 8(%esp)
        movl    %ecx, 4(%esp)
        movl    $.LC0, (%esp)
        call    printf

PS: The "asm" syntax is applicable to all gcc-based compilers.

PPS: I absolutely encourage you to experiment with assembly anywhere you please: embedded systems, Ubuntu, Mac OSX - whatever pleases you.

Here is an excellent book. It's about Linux, but it's also very largely applicable to your OSX:

Programming from the Ground Up, Jonathan Bartlett




PPS: x86 assembly syntax comes in two variants: "Intel" and "ATT" syntax. Gcc uses ATT. The ATT syntax is also applicable for any other architecture supported by GCC (MIPS, PPC, etc etc). I encourage you to start off with ATT syntax ("gcc/gas"), rather than Intel ("nasm").

  • Thanks a lot. But I still don't understand why gcc couldn't successfully compile it into executable while clang could. I will read your suggested articles and try to understand the assembly code that clang produced. – ZLW Dec 27 '14 at 22:13
  • Hi - Glad it helped. For whatever it's worth, I actually compiled the snippet above (cut/pasted from your code) on two versions of GCC: 32-bit Centos 5.5 and 64-bit CentOS 6.4. It compiled ("assembled" ;)) fine, but I didn't trying linking or executing either version. – FoggyDay Dec 28 '14 at 1:23

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